Department of Mechanical & Industrial Engineering, Institute of Biomaterials & Biomedical Engineering, University of Toronto, Toronto, ON, Canada.
Lab Chip. 2018 May 1;18(9):1298-1309. doi: 10.1039/c7lc01357d.
Chronic lung diseases (CLDs) are regulated by complex interactions between many different cell types residing in lung airway tissues. Specifically, interactions between airway epithelial cells (ECs) and airway smooth muscle cells (SMCs) have been shown in part to play major roles in the pathogenesis of CLDs, but the underlying molecular mechanisms are not well understood. To advance our understanding of lung pathophysiology and accelerate drug development processes, new innovative in vitro tissue models are needed that can reconstitute the complex in vivo microenvironment of human lung tissues. Organ-on-a-chip technologies have recently made significant strides in recapitulating physiological properties of in vivo lung tissue microenvironments. However, novel advancements are still needed to enable the study of airway SMC-EC communication with matrix interactions, and to provide higher throughput capabilities and manufacturability. We have developed a thermoplastic-based microfluidic lung airway-on-a-chip model that mimics the lung airway tissue microenvironment, and in particular, the interactions between SMCs, ECs, and supporting extracellular matrix (ECM). The microdevice is fabricated from acrylic using micromilling and solvent bonding techniques, and consists of three vertically stacked microfluidic compartments with a bottom media reservoir for SMC culture, a middle thin hydrogel layer, and an upper microchamber for achieving air-liquid interface (ALI) culture of the epithelium. A unique aspect of the design lies in the suspended hydrogel with upper and lower interfaces for EC and SMC culture, respectively. A mixture of type I collagen and Matrigel was found to promote EC adhesion and monolayer formation, and SMC adhesion and alignment. Optimal culturing protocols were established that enabled EC-SMC coculture for more than 31 days. Epithelial monolayers displayed common morphological markers including ZO-1 tight junctions and F-actin cell cortices, while SMCs exhibited enhanced cell alignment and expression of α-SMA. The thermoplastic device construction facilitates mass manufacturing, allows EC-SMC coculture systems to be arrayed for increased throughput, and can be disassembled to allow extraction of the suspended gel for downstream analyses. This airway-on-a-chip device has potential to significantly advance our understanding of SMC-EC-matrix interactions, and their roles in the development of CLDs.
慢性肺部疾病(CLD)是由驻留在肺部气道组织中的许多不同细胞类型之间的复杂相互作用所调控的。具体而言,气道上皮细胞(ECs)和气道平滑肌细胞(SMCs)之间的相互作用已被部分证明在 CLD 的发病机制中起主要作用,但潜在的分子机制尚不清楚。为了增进我们对肺部病理生理学的理解并加速药物开发过程,需要新的创新型体外组织模型,以重新构建人体肺部组织的复杂体内微环境。器官芯片技术最近在再现体内肺组织微环境的生理特性方面取得了重大进展。然而,仍需要新的进展来实现气道平滑肌细胞-EC 与基质相互作用的研究,并提供更高的通量能力和可制造性。我们已经开发了一种基于热塑性的微流控肺气道芯片模型,该模型模拟了肺部气道组织的微环境,特别是平滑肌细胞、EC 和支持细胞外基质(ECM)之间的相互作用。该微器件是使用微铣削和溶剂键合技术由丙烯酸制成的,由三个垂直堆叠的微流控隔室组成,底部为平滑肌细胞培养的介质储层、中间为薄水凝胶层、上部为实现上皮细胞气液界面(ALI)培养的微室。设计的一个独特方面在于悬浮水凝胶,其上下界面分别用于 EC 和 SMC 的培养。发现 I 型胶原和 Matrigel 的混合物可促进 EC 黏附和单层形成,以及 SMC 黏附和排列。建立了最佳的培养方案,使 EC-SMC 共培养超过 31 天。上皮单层显示出共同的形态学标志物,包括 ZO-1 紧密连接和 F-肌动蛋白细胞皮质,而 SMC 则表现出增强的细胞排列和 α-SMA 的表达。热塑性器件的结构便于大规模制造,允许将 EC-SMC 共培养系统排列以提高通量,并且可以拆卸以提取悬浮凝胶进行下游分析。这种气道芯片装置有可能显著增进我们对 SMC-EC-基质相互作用及其在 CLD 发展中的作用的理解。
